# orm/__init__.py
# Copyright (C) 2005-2013 the SQLAlchemy authors and contributors <see AUTHORS file>
#
# This module is part of SQLAlchemy and is released under
# the MIT License: http://www.opensource.org/licenses/mit-license.php

"""
Functional constructs for ORM configuration.

See the SQLAlchemy object relational tutorial and mapper configuration
documentation for an overview of how this module is used.

"""

from . import exc
from .mapper import (
     Mapper,
     _mapper_registry,
     class_mapper,
     configure_mappers,
     reconstructor,
     validates
     )
from .interfaces import (
     EXT_CONTINUE,
     EXT_STOP,
     MapperExtension,
     PropComparator,
     SessionExtension,
     AttributeExtension,
     )
from .util import (
     aliased,
     join,
     object_mapper,
     outerjoin,
     polymorphic_union,
     was_deleted,
     with_parent,
     with_polymorphic,
     )
from .properties import (
     ColumnProperty,
     ComparableProperty,
     CompositeProperty,
     RelationshipProperty,
     PropertyLoader,
     SynonymProperty,
     )
from .relationships import (
    foreign,
    remote,
)
from .session import (
    Session,
    object_session,
    sessionmaker,
    make_transient
)
from .scoping import (
    scoped_session
)
from . import mapper as mapperlib
from . import strategies
from .query import AliasOption, Query
from ..sql import util as sql_util
from .. import util as sa_util

from . import interfaces

# here, we can establish InstrumentationManager back
# in sqlalchemy.orm and sqlalchemy.orm.interfaces, which
# also re-establishes the extended instrumentation system.
#from ..ext import instrumentation as _ext_instrumentation
#InstrumentationManager = \
#    interfaces.InstrumentationManager = \
#    _ext_instrumentation.InstrumentationManager

__all__ = (
    'EXT_CONTINUE',
    'EXT_STOP',
    'MapperExtension',
    'AttributeExtension',
    'PropComparator',
    'Query',
    'Session',
    'aliased',
    'backref',
    'class_mapper',
    'clear_mappers',
    'column_property',
    'comparable_property',
    'compile_mappers',
    'configure_mappers',
    'composite',
    'contains_alias',
    'contains_eager',
    'create_session',
    'defer',
    'deferred',
    'dynamic_loader',
    'eagerload',
    'eagerload_all',
    'foreign',
    'immediateload',
    'join',
    'joinedload',
    'joinedload_all',
    'lazyload',
    'mapper',
    'make_transient',
    'noload',
    'object_mapper',
    'object_session',
    'outerjoin',
    'polymorphic_union',
    'reconstructor',
    'relationship',
    'relation',
    'remote',
    'scoped_session',
    'sessionmaker',
    'subqueryload',
    'subqueryload_all',
    'synonym',
    'undefer',
    'undefer_group',
    'validates',
    'was_deleted',
    'with_polymorphic'
    )


def create_session(bind=None, **kwargs):
    """Create a new :class:`.Session`
    with no automation enabled by default.

    This function is used primarily for testing.   The usual
    route to :class:`.Session` creation is via its constructor
    or the :func:`.sessionmaker` function.

    :param bind: optional, a single Connectable to use for all
      database access in the created
      :class:`~sqlalchemy.orm.session.Session`.

    :param \*\*kwargs: optional, passed through to the
      :class:`.Session` constructor.

    :returns: an :class:`~sqlalchemy.orm.session.Session` instance

    The defaults of create_session() are the opposite of that of
    :func:`sessionmaker`; ``autoflush`` and ``expire_on_commit`` are
    False, ``autocommit`` is True.  In this sense the session acts
    more like the "classic" SQLAlchemy 0.3 session with these.

    Usage::

      >>> from sqlalchemy.orm import create_session
      >>> session = create_session()

    It is recommended to use :func:`sessionmaker` instead of
    create_session().

    """
    kwargs.setdefault('autoflush', False)
    kwargs.setdefault('autocommit', True)
    kwargs.setdefault('expire_on_commit', False)
    return Session(bind=bind, **kwargs)


def relationship(argument, secondary=None, **kwargs):
    """Provide a relationship of a primary Mapper to a secondary Mapper.

    This corresponds to a parent-child or associative table relationship.  The
    constructed class is an instance of :class:`.RelationshipProperty`.

    A typical :func:`.relationship`, used in a classical mapping::

       mapper(Parent, properties={
         'children': relationship(Child)
       })

    Some arguments accepted by :func:`.relationship` optionally accept a
    callable function, which when called produces the desired value.
    The callable is invoked by the parent :class:`.Mapper` at "mapper
    initialization" time, which happens only when mappers are first used, and
    is assumed to be after all mappings have been constructed.  This can be
    used to resolve order-of-declaration and other dependency issues, such as
    if ``Child`` is declared below ``Parent`` in the same file::

        mapper(Parent, properties={
            "children":relationship(lambda: Child,
                                order_by=lambda: Child.id)
        })

    When using the :ref:`declarative_toplevel` extension, the Declarative
    initializer allows string arguments to be passed to :func:`.relationship`.
    These string arguments are converted into callables that evaluate
    the string as Python code, using the Declarative
    class-registry as a namespace.  This allows the lookup of related
    classes to be automatic via their string name, and removes the need to
    import related classes at all into the local module space::

        from sqlalchemy.ext.declarative import declarative_base

        Base = declarative_base()

        class Parent(Base):
            __tablename__ = 'parent'
            id = Column(Integer, primary_key=True)
            children = relationship("Child", order_by="Child.id")

    A full array of examples and reference documentation regarding
    :func:`.relationship` is at :ref:`relationship_config_toplevel`.

    :param argument:
      a mapped class, or actual :class:`.Mapper` instance, representing the
      target of the relationship.

      ``argument`` may also be passed as a callable function
      which is evaluated at mapper initialization time, and may be passed as a
      Python-evaluable string when using Declarative.

    :param secondary:
      for a many-to-many relationship, specifies the intermediary
      table, and is an instance of :class:`.Table`.  The ``secondary`` keyword
      argument should generally only
      be used for a table that is not otherwise expressed in any class
      mapping, unless this relationship is declared as view only, otherwise
      conflicting persistence operations can occur.

      ``secondary`` may
      also be passed as a callable function which is evaluated at
      mapper initialization time.

    :param active_history=False:
      When ``True``, indicates that the "previous" value for a
      many-to-one reference should be loaded when replaced, if
      not already loaded. Normally, history tracking logic for
      simple many-to-ones only needs to be aware of the "new"
      value in order to perform a flush. This flag is available
      for applications that make use of
      :func:`.attributes.get_history` which also need to know
      the "previous" value of the attribute.

    :param backref:
      indicates the string name of a property to be placed on the related
      mapper's class that will handle this relationship in the other
      direction. The other property will be created automatically
      when the mappers are configured.  Can also be passed as a
      :func:`backref` object to control the configuration of the
      new relationship.

    :param back_populates:
      Takes a string name and has the same meaning as ``backref``,
      except the complementing property is **not** created automatically,
      and instead must be configured explicitly on the other mapper.  The
      complementing property should also indicate ``back_populates``
      to this relationship to ensure proper functioning.

    :param cascade:
      a comma-separated list of cascade rules which determines how
      Session operations should be "cascaded" from parent to child.
      This defaults to ``False``, which means the default cascade
      should be used.  The default value is ``"save-update, merge"``.

      Available cascades are:

      * ``save-update`` - cascade the :meth:`.Session.add`
        operation.  This cascade applies both to future and
        past calls to :meth:`~sqlalchemy.orm.session.Session.add`,
        meaning new items added to a collection or scalar relationship
        get placed into the same session as that of the parent, and
        also applies to items which have been removed from this
        relationship but are still part of unflushed history.

      * ``merge`` - cascade the :meth:`~sqlalchemy.orm.session.Session.merge`
        operation

      * ``expunge`` - cascade the :meth:`.Session.expunge`
        operation

      * ``delete`` - cascade the :meth:`.Session.delete`
        operation

      * ``delete-orphan`` - if an item of the child's type is
        detached from its parent, mark it for deletion.

        .. versionchanged:: 0.7
            This option does not prevent
            a new instance of the child object from being persisted
            without a parent to start with; to constrain against
            that case, ensure the child's foreign key column(s)
            is configured as NOT NULL

      * ``refresh-expire`` - cascade the :meth:`.Session.expire`
        and :meth:`~sqlalchemy.orm.session.Session.refresh` operations

      * ``all`` - shorthand for "save-update,merge, refresh-expire,
        expunge, delete"

     See the section :ref:`unitofwork_cascades` for more background
     on configuring cascades.

    :param cascade_backrefs=True:
      a boolean value indicating if the ``save-update`` cascade should
      operate along an assignment event intercepted by a backref.
      When set to ``False``,
      the attribute managed by this relationship will not cascade
      an incoming transient object into the session of a
      persistent parent, if the event is received via backref.

      That is::

        mapper(A, a_table, properties={
            'bs':relationship(B, backref="a", cascade_backrefs=False)
        })

      If an ``A()`` is present in the session, assigning it to
      the "a" attribute on a transient ``B()`` will not place
      the ``B()`` into the session.   To set the flag in the other
      direction, i.e. so that ``A().bs.append(B())`` won't add
      a transient ``A()`` into the session for a persistent ``B()``::

        mapper(A, a_table, properties={
            'bs':relationship(B,
                    backref=backref("a", cascade_backrefs=False)
                )
        })

      See the section :ref:`unitofwork_cascades` for more background
      on configuring cascades.

    :param collection_class:
      a class or callable that returns a new list-holding object. will
      be used in place of a plain list for storing elements.
      Behavior of this attribute is described in detail at
      :ref:`custom_collections`.

    :param comparator_factory:
      a class which extends :class:`.RelationshipProperty.Comparator` which
      provides custom SQL clause generation for comparison operations.

    :param doc:
      docstring which will be applied to the resulting descriptor.

    :param extension:
      an :class:`.AttributeExtension` instance, or list of extensions,
      which will be prepended to the list of attribute listeners for
      the resulting descriptor placed on the class.
      **Deprecated.**  Please see :class:`.AttributeEvents`.

    :param foreign_keys:
      a list of columns which are to be used as "foreign key" columns,
      or columns which refer to the value in a remote column, within the
      context of this :func:`.relationship` object's ``primaryjoin``
      condition.   That is, if the ``primaryjoin`` condition of this
      :func:`.relationship` is ``a.id == b.a_id``, and the values in ``b.a_id``
      are required to be present in ``a.id``, then the "foreign key" column
      of this :func:`.relationship` is ``b.a_id``.

      In normal cases, the ``foreign_keys`` parameter is **not required.**
      :func:`.relationship` will **automatically** determine which columns
      in the ``primaryjoin`` conditition are to be considered "foreign key"
      columns based on those :class:`.Column` objects that specify
      :class:`.ForeignKey`, or are otherwise listed as referencing columns
      in a :class:`.ForeignKeyConstraint` construct.  ``foreign_keys`` is only
      needed when:

        1. There is more than one way to construct a join from the local
           table to the remote table, as there are multiple foreign key
           references present.  Setting ``foreign_keys`` will limit the
           :func:`.relationship` to consider just those columns specified
           here as "foreign".

           .. versionchanged:: 0.8
                A multiple-foreign key join ambiguity can be resolved by
                setting the ``foreign_keys`` parameter alone, without the
                need to explicitly set ``primaryjoin`` as well.

        2. The :class:`.Table` being mapped does not actually have
           :class:`.ForeignKey` or :class:`.ForeignKeyConstraint`
           constructs present, often because the table
           was reflected from a database that does not support foreign key
           reflection (MySQL MyISAM).

        3. The ``primaryjoin`` argument is used to construct a non-standard
           join condition, which makes use of columns or expressions that do
           not normally refer to their "parent" column, such as a join condition
           expressed by a complex comparison using a SQL function.

      The :func:`.relationship` construct will raise informative error messages
      that suggest the use of the ``foreign_keys`` parameter when presented
      with an ambiguous condition.   In typical cases, if :func:`.relationship`
      doesn't raise any exceptions, the ``foreign_keys`` parameter is usually
      not needed.

      ``foreign_keys`` may also be passed as a callable function
      which is evaluated at mapper initialization time, and may be passed as a
      Python-evaluable string when using Declarative.

      .. seealso::

        :ref:`relationship_foreign_keys`

        :ref:`relationship_custom_foreign`

        :func:`.foreign` - allows direct annotation of the "foreign" columns
        within a ``primaryjoin`` condition.

      .. versionadded:: 0.8
          The :func:`.foreign` annotation can also be applied
          directly to the ``primaryjoin`` expression, which is an alternate,
          more specific system of describing which columns in a particular
          ``primaryjoin`` should be considered "foreign".

    :param info: Optional data dictionary which will be populated into the
        :attr:`.MapperProperty.info` attribute of this object.

        .. versionadded:: 0.8

    :param innerjoin=False:
      when ``True``, joined eager loads will use an inner join to join
      against related tables instead of an outer join.  The purpose
      of this option is generally one of performance, as inner joins
      generally perform better than outer joins. Another reason can be
      the use of ``with_lockmode``, which does not support outer joins.

      This flag can be set to ``True`` when the relationship references an
      object via many-to-one using local foreign keys that are not nullable,
      or when the reference is one-to-one or a collection that is guaranteed
      to have one or at least one entry.

    :param join_depth:
      when non-``None``, an integer value indicating how many levels
      deep "eager" loaders should join on a self-referring or cyclical
      relationship.  The number counts how many times the same Mapper
      shall be present in the loading condition along a particular join
      branch.  When left at its default of ``None``, eager loaders
      will stop chaining when they encounter a the same target mapper
      which is already higher up in the chain.  This option applies
      both to joined- and subquery- eager loaders.

    :param lazy='select': specifies
      how the related items should be loaded.  Default value is
      ``select``.  Values include:

      * ``select`` - items should be loaded lazily when the property is first
        accessed, using a separate SELECT statement, or identity map
        fetch for simple many-to-one references.

      * ``immediate`` - items should be loaded as the parents are loaded,
        using a separate SELECT statement, or identity map fetch for
        simple many-to-one references.

        .. versionadded:: 0.6.5

      * ``joined`` - items should be loaded "eagerly" in the same query as
        that of the parent, using a JOIN or LEFT OUTER JOIN.  Whether
        the join is "outer" or not is determined by the ``innerjoin``
        parameter.

      * ``subquery`` - items should be loaded "eagerly" as the parents are
        loaded, using one additional SQL statement, which issues a JOIN to a
        subquery of the original statement, for each collection requested.

      * ``noload`` - no loading should occur at any time.  This is to
        support "write-only" attributes, or attributes which are
        populated in some manner specific to the application.

      * ``dynamic`` - the attribute will return a pre-configured
        :class:`~sqlalchemy.orm.query.Query` object for all read
        operations, onto which further filtering operations can be
        applied before iterating the results.  See
        the section :ref:`dynamic_relationship` for more details.

      * True - a synonym for 'select'

      * False - a synonym for 'joined'

      * None - a synonym for 'noload'

      Detailed discussion of loader strategies is at :doc:`/orm/loading`.

    :param load_on_pending=False:
      Indicates loading behavior for transient or pending parent objects.

      .. versionchanged:: 0.8
          load_on_pending is superseded by
          :meth:`.Session.enable_relationship_loading`.

      When set to ``True``, causes the lazy-loader to
      issue a query for a parent object that is not persistent, meaning it has
      never been flushed.  This may take effect for a pending object when
      autoflush is disabled, or for a transient object that has been
      "attached" to a :class:`.Session` but is not part of its pending
      collection.

      The load_on_pending flag does not improve behavior
      when the ORM is used normally - object references should be constructed
      at the object level, not at the foreign key level, so that they
      are present in an ordinary way before flush() proceeds.  This flag
      is not not intended for general use.

      .. versionadded:: 0.6.5

    :param order_by:
      indicates the ordering that should be applied when loading these
      items.  ``order_by`` is expected to refer to one of the :class:`.Column`
      objects to which the target class is mapped, or
      the attribute itself bound to the target class which refers
      to the column.

      ``order_by`` may also be passed as a callable function
      which is evaluated at mapper initialization time, and may be passed as a
      Python-evaluable string when using Declarative.

    :param passive_deletes=False:
       Indicates loading behavior during delete operations.

       A value of True indicates that unloaded child items should not
       be loaded during a delete operation on the parent.  Normally,
       when a parent item is deleted, all child items are loaded so
       that they can either be marked as deleted, or have their
       foreign key to the parent set to NULL.  Marking this flag as
       True usually implies an ON DELETE <CASCADE|SET NULL> rule is in
       place which will handle updating/deleting child rows on the
       database side.

       Additionally, setting the flag to the string value 'all' will
       disable the "nulling out" of the child foreign keys, when there
       is no delete or delete-orphan cascade enabled.  This is
       typically used when a triggering or error raise scenario is in
       place on the database side.  Note that the foreign key
       attributes on in-session child objects will not be changed
       after a flush occurs so this is a very special use-case
       setting.

    :param passive_updates=True:
      Indicates loading and INSERT/UPDATE/DELETE behavior when the
      source of a foreign key value changes (i.e. an "on update"
      cascade), which are typically the primary key columns of the
      source row.

      When True, it is assumed that ON UPDATE CASCADE is configured on
      the foreign key in the database, and that the database will
      handle propagation of an UPDATE from a source column to
      dependent rows.  Note that with databases which enforce
      referential integrity (i.e. PostgreSQL, MySQL with InnoDB tables),
      ON UPDATE CASCADE is required for this operation.  The
      relationship() will update the value of the attribute on related
      items which are locally present in the session during a flush.

      When False, it is assumed that the database does not enforce
      referential integrity and will not be issuing its own CASCADE
      operation for an update.  The relationship() will issue the
      appropriate UPDATE statements to the database in response to the
      change of a referenced key, and items locally present in the
      session during a flush will also be refreshed.

      This flag should probably be set to False if primary key changes
      are expected and the database in use doesn't support CASCADE
      (i.e. SQLite, MySQL MyISAM tables).

      Also see the passive_updates flag on ``mapper()``.

      A future SQLAlchemy release will provide a "detect" feature for
      this flag.

    :param post_update:
      this indicates that the relationship should be handled by a
      second UPDATE statement after an INSERT or before a
      DELETE. Currently, it also will issue an UPDATE after the
      instance was UPDATEd as well, although this technically should
      be improved. This flag is used to handle saving bi-directional
      dependencies between two individual rows (i.e. each row
      references the other), where it would otherwise be impossible to
      INSERT or DELETE both rows fully since one row exists before the
      other. Use this flag when a particular mapping arrangement will
      incur two rows that are dependent on each other, such as a table
      that has a one-to-many relationship to a set of child rows, and
      also has a column that references a single child row within that
      list (i.e. both tables contain a foreign key to each other). If
      a ``flush()`` operation returns an error that a "cyclical
      dependency" was detected, this is a cue that you might want to
      use ``post_update`` to "break" the cycle.

    :param primaryjoin:
      a SQL expression that will be used as the primary
      join of this child object against the parent object, or in a
      many-to-many relationship the join of the primary object to the
      association table. By default, this value is computed based on the
      foreign key relationships of the parent and child tables (or association
      table).

      ``primaryjoin`` may also be passed as a callable function
      which is evaluated at mapper initialization time, and may be passed as a
      Python-evaluable string when using Declarative.

    :param remote_side:
      used for self-referential relationships, indicates the column or
      list of columns that form the "remote side" of the relationship.

      ``remote_side`` may also be passed as a callable function
      which is evaluated at mapper initialization time, and may be passed as a
      Python-evaluable string when using Declarative.

      .. versionchanged:: 0.8
          The :func:`.remote` annotation can also be applied
          directly to the ``primaryjoin`` expression, which is an alternate,
          more specific system of describing which columns in a particular
          ``primaryjoin`` should be considered "remote".

    :param query_class:
      a :class:`.Query` subclass that will be used as the base of the
      "appender query" returned by a "dynamic" relationship, that
      is, a relationship that specifies ``lazy="dynamic"`` or was
      otherwise constructed using the :func:`.orm.dynamic_loader`
      function.

    :param secondaryjoin:
      a SQL expression that will be used as the join of
      an association table to the child object. By default, this value is
      computed based on the foreign key relationships of the association and
      child tables.

      ``secondaryjoin`` may also be passed as a callable function
      which is evaluated at mapper initialization time, and may be passed as a
      Python-evaluable string when using Declarative.

    :param single_parent=(True|False):
      when True, installs a validator which will prevent objects
      from being associated with more than one parent at a time.
      This is used for many-to-one or many-to-many relationships that
      should be treated either as one-to-one or one-to-many.  Its
      usage is optional unless delete-orphan cascade is also
      set on this relationship(), in which case its required.

    :param uselist=(True|False):
      a boolean that indicates if this property should be loaded as a
      list or a scalar. In most cases, this value is determined
      automatically by ``relationship()``, based on the type and direction
      of the relationship - one to many forms a list, many to one
      forms a scalar, many to many is a list. If a scalar is desired
      where normally a list would be present, such as a bi-directional
      one-to-one relationship, set uselist to False.

    :param viewonly=False:
      when set to True, the relationship is used only for loading objects
      within the relationship, and has no effect on the unit-of-work
      flush process.  Relationships with viewonly can specify any kind of
      join conditions to provide additional views of related objects
      onto a parent object. Note that the functionality of a viewonly
      relationship has its limits - complicated join conditions may
      not compile into eager or lazy loaders properly. If this is the
      case, use an alternative method.

    .. versionchanged:: 0.6
        :func:`relationship` was renamed from its previous name
        :func:`relation`.

    """
    return RelationshipProperty(argument, secondary=secondary, **kwargs)


def relation(*arg, **kw):
    """A synonym for :func:`relationship`."""

    return relationship(*arg, **kw)


def dynamic_loader(argument, **kw):
    """Construct a dynamically-loading mapper property.

    This is essentially the same as
    using the ``lazy='dynamic'`` argument with :func:`relationship`::

        dynamic_loader(SomeClass)

        # is the same as

        relationship(SomeClass, lazy="dynamic")

    See the section :ref:`dynamic_relationship` for more details
    on dynamic loading.

    """
    kw['lazy'] = 'dynamic'
    return relationship(argument, **kw)


def column_property(*cols, **kw):
    """Provide a column-level property for use with a Mapper.

    Column-based properties can normally be applied to the mapper's
    ``properties`` dictionary using the :class:`.Column` element directly.
    Use this function when the given column is not directly present within the
    mapper's selectable; examples include SQL expressions, functions, and
    scalar SELECT queries.

    Columns that aren't present in the mapper's selectable won't be persisted
    by the mapper and are effectively "read-only" attributes.

    :param \*cols:
          list of Column objects to be mapped.

    :param active_history=False:
      When ``True``, indicates that the "previous" value for a
      scalar attribute should be loaded when replaced, if not
      already loaded. Normally, history tracking logic for
      simple non-primary-key scalar values only needs to be
      aware of the "new" value in order to perform a flush. This
      flag is available for applications that make use of
      :func:`.attributes.get_history` or :meth:`.Session.is_modified`
      which also need to know
      the "previous" value of the attribute.

      .. versionadded:: 0.6.6

    :param comparator_factory: a class which extends
       :class:`.ColumnProperty.Comparator` which provides custom SQL clause
       generation for comparison operations.

    :param group:
        a group name for this property when marked as deferred.

    :param deferred:
          when True, the column property is "deferred", meaning that
          it does not load immediately, and is instead loaded when the
          attribute is first accessed on an instance.  See also
          :func:`~sqlalchemy.orm.deferred`.

    :param doc:
          optional string that will be applied as the doc on the
          class-bound descriptor.

    :param expire_on_flush=True:
        Disable expiry on flush.   A column_property() which refers
        to a SQL expression (and not a single table-bound column)
        is considered to be a "read only" property; populating it
        has no effect on the state of data, and it can only return
        database state.   For this reason a column_property()'s value
        is expired whenever the parent object is involved in a
        flush, that is, has any kind of "dirty" state within a flush.
        Setting this parameter to ``False`` will have the effect of
        leaving any existing value present after the flush proceeds.
        Note however that the :class:`.Session` with default expiration
        settings still expires
        all attributes after a :meth:`.Session.commit` call, however.

        .. versionadded:: 0.7.3

    :param info: Optional data dictionary which will be populated into the
        :attr:`.MapperProperty.info` attribute of this object.

        .. versionadded:: 0.8

    :param extension:
        an
        :class:`.AttributeExtension`
        instance, or list of extensions, which will be prepended
        to the list of attribute listeners for the resulting
        descriptor placed on the class.
        **Deprecated.** Please see :class:`.AttributeEvents`.

    """

    return ColumnProperty(*cols, **kw)


def composite(class_, *cols, **kwargs):
    """Return a composite column-based property for use with a Mapper.

    See the mapping documentation section :ref:`mapper_composite` for a full
    usage example.

    The :class:`.MapperProperty` returned by :func:`.composite`
    is the :class:`.CompositeProperty`.

    :param class\_:
      The "composite type" class.

    :param \*cols:
      List of Column objects to be mapped.

    :param active_history=False:
      When ``True``, indicates that the "previous" value for a
      scalar attribute should be loaded when replaced, if not
      already loaded.  See the same flag on :func:`.column_property`.

      .. versionchanged:: 0.7
          This flag specifically becomes meaningful
          - previously it was a placeholder.

    :param group:
      A group name for this property when marked as deferred.

    :param deferred:
      When True, the column property is "deferred", meaning that it does not
      load immediately, and is instead loaded when the attribute is first
      accessed on an instance.  See also :func:`~sqlalchemy.orm.deferred`.

    :param comparator_factory:  a class which extends
      :class:`.CompositeProperty.Comparator` which provides custom SQL clause
      generation for comparison operations.

    :param doc:
      optional string that will be applied as the doc on the
      class-bound descriptor.

    :param info: Optional data dictionary which will be populated into the
        :attr:`.MapperProperty.info` attribute of this object.

        .. versionadded:: 0.8

    :param extension:
      an :class:`.AttributeExtension` instance,
      or list of extensions, which will be prepended to the list of
      attribute listeners for the resulting descriptor placed on the class.
      **Deprecated.**  Please see :class:`.AttributeEvents`.

    """
    return CompositeProperty(class_, *cols, **kwargs)


def backref(name, **kwargs):
    """Create a back reference with explicit keyword arguments, which are the
    same arguments one can send to :func:`relationship`.

    Used with the ``backref`` keyword argument to :func:`relationship` in
    place of a string argument, e.g.::

        'items':relationship(SomeItem, backref=backref('parent', lazy='subquery'))

    """
    return (name, kwargs)


def deferred(*columns, **kwargs):
    """Return a :class:`.DeferredColumnProperty`, which indicates this
    object attributes should only be loaded from its corresponding
    table column when first accessed.

    Used with the "properties" dictionary sent to :func:`mapper`.

    See also:

    :ref:`deferred`

    """
    return ColumnProperty(deferred=True, *columns, **kwargs)


def mapper(class_, local_table=None, *args, **params):
    """Return a new :class:`~.Mapper` object.

        This function is typically used behind the scenes
        via the Declarative extension.   When using Declarative,
        many of the usual :func:`.mapper` arguments are handled
        by the Declarative extension itself, including ``class_``,
        ``local_table``, ``properties``, and  ``inherits``.
        Other options are passed to :func:`.mapper` using
        the ``__mapper_args__`` class variable::

           class MyClass(Base):
               __tablename__ = 'my_table'
               id = Column(Integer, primary_key=True)
               type = Column(String(50))
               alt = Column("some_alt", Integer)

               __mapper_args__ = {
                   'polymorphic_on' : type
               }


        Explicit use of :func:`.mapper`
        is often referred to as *classical mapping*.  The above
        declarative example is equivalent in classical form to::

            my_table = Table("my_table", metadata,
                Column('id', Integer, primary_key=True),
                Column('type', String(50)),
                Column("some_alt", Integer)
            )

            class MyClass(object):
                pass

            mapper(MyClass, my_table,
                polymorphic_on=my_table.c.type,
                properties={
                    'alt':my_table.c.some_alt
                })

        See also:

        :ref:`classical_mapping` - discussion of direct usage of
        :func:`.mapper`

        :param class\_: The class to be mapped.  When using Declarative,
          this argument is automatically passed as the declared class
          itself.

        :param local_table: The :class:`.Table` or other selectable
           to which the class is mapped.  May be ``None`` if
           this mapper inherits from another mapper using single-table
           inheritance.   When using Declarative, this argument is
           automatically passed by the extension, based on what
           is configured via the ``__table__`` argument or via the
           :class:`.Table` produced as a result of the ``__tablename__``
           and :class:`.Column` arguments present.

        :param always_refresh: If True, all query operations for this mapped
           class will overwrite all data within object instances that already
           exist within the session, erasing any in-memory changes with
           whatever information was loaded from the database. Usage of this
           flag is highly discouraged; as an alternative, see the method
           :meth:`.Query.populate_existing`.

        :param allow_partial_pks: Defaults to True.  Indicates that a
           composite primary key with some NULL values should be considered as
           possibly existing within the database. This affects whether a
           mapper will assign an incoming row to an existing identity, as well
           as if :meth:`.Session.merge` will check the database first for a
           particular primary key value. A "partial primary key" can occur if
           one has mapped to an OUTER JOIN, for example.

        :param batch: Defaults to ``True``, indicating that save operations
           of multiple entities can be batched together for efficiency.
           Setting to False indicates
           that an instance will be fully saved before saving the next
           instance.  This is used in the extremely rare case that a
           :class:`.MapperEvents` listener requires being called
           in between individual row persistence operations.

        :param column_prefix: A string which will be prepended
           to the mapped attribute name when :class:`.Column`
           objects are automatically assigned as attributes to the
           mapped class.  Does not affect explicitly specified
           column-based properties.

           See the section :ref:`column_prefix` for an example.

        :param concrete: If True, indicates this mapper should use concrete
           table inheritance with its parent mapper.

           See the section :ref:`concrete_inheritance` for an example.

        :param exclude_properties: A list or set of string column names to
          be excluded from mapping.

          See :ref:`include_exclude_cols` for an example.

        :param extension: A :class:`.MapperExtension` instance or
           list of :class:`.MapperExtension` instances which will be applied
           to all operations by this :class:`.Mapper`.  **Deprecated.**
           Please see :class:`.MapperEvents`.

        :param include_properties: An inclusive list or set of string column
          names to map.

          See :ref:`include_exclude_cols` for an example.

        :param inherits: A mapped class or the corresponding :class:`.Mapper`
          of one indicating a superclass to which this :class:`.Mapper`
          should *inherit* from.   The mapped class here must be a subclass
          of the other mapper's class.   When using Declarative, this argument
          is passed automatically as a result of the natural class
          hierarchy of the declared classes.

          See also:

          :ref:`inheritance_toplevel`

        :param inherit_condition: For joined table inheritance, a SQL
           expression which will
           define how the two tables are joined; defaults to a natural join
           between the two tables.

        :param inherit_foreign_keys: When ``inherit_condition`` is used and the
           columns present are missing a :class:`.ForeignKey` configuration,
           this parameter can be used to specify which columns are "foreign".
           In most cases can be left as ``None``.

        :param legacy_is_orphan: Boolean, defaults to ``False``.
          When ``True``, specifies that "legacy" orphan consideration
          is to be applied to objects mapped by this mapper, which means
          that a pending (that is, not persistent) object is auto-expunged
          from an owning :class:`.Session` only when it is de-associated
          from *all* parents that specify a ``delete-orphan`` cascade towards
          this mapper.  The new default behavior is that the object is auto-expunged
          when it is de-associated with *any* of its parents that specify
          ``delete-orphan`` cascade.  This behavior is more consistent with
          that of a persistent object, and allows behavior to be consistent
          in more scenarios independently of whether or not an orphanable
          object has been flushed yet or not.

          See the change note and example at :ref:`legacy_is_orphan_addition`
          for more detail on this change.

          .. versionadded:: 0.8 - the consideration of a pending object as
            an "orphan" has been modified to more closely match the
            behavior as that of persistent objects, which is that the object
            is expunged from the :class:`.Session` as soon as it is
            de-associated from any of its orphan-enabled parents.  Previously,
            the pending object would be expunged only if de-associated
            from all of its orphan-enabled parents. The new flag ``legacy_is_orphan``
            is added to :func:`.orm.mapper` which re-establishes the
            legacy behavior.

        :param non_primary: Specify that this :class:`.Mapper` is in addition
          to the "primary" mapper, that is, the one used for persistence.
          The :class:`.Mapper` created here may be used for ad-hoc
          mapping of the class to an alternate selectable, for loading
          only.

          The ``non_primary`` feature is rarely needed with modern
          usage.

        :param order_by: A single :class:`.Column` or list of :class:`.Column`
           objects for which selection operations should use as the default
           ordering for entities.  By default mappers have no pre-defined
           ordering.

        :param passive_updates: Indicates UPDATE behavior of foreign key
           columns when a primary key column changes on a joined-table
           inheritance mapping.   Defaults to ``True``.

           When True, it is assumed that ON UPDATE CASCADE is configured on
           the foreign key in the database, and that the database will handle
           propagation of an UPDATE from a source column to dependent columns
           on joined-table rows.

           When False, it is assumed that the database does not enforce
           referential integrity and will not be issuing its own CASCADE
           operation for an update.  The :class:`.Mapper` here will
           emit an UPDATE statement for the dependent columns during a
           primary key change.

           See also:

           :ref:`passive_updates` - description of a similar feature as
           used with :func:`.relationship`

        :param polymorphic_on: Specifies the column, attribute, or
          SQL expression used to determine the target class for an
          incoming row, when inheriting classes are present.

          This value is commonly a :class:`.Column` object that's
          present in the mapped :class:`.Table`::

            class Employee(Base):
                __tablename__ = 'employee'

                id = Column(Integer, primary_key=True)
                discriminator = Column(String(50))

                __mapper_args__ = {
                    "polymorphic_on":discriminator,
                    "polymorphic_identity":"employee"
                }

          It may also be specified
          as a SQL expression, as in this example where we
          use the :func:`.case` construct to provide a conditional
          approach::

            class Employee(Base):
                __tablename__ = 'employee'

                id = Column(Integer, primary_key=True)
                discriminator = Column(String(50))

                __mapper_args__ = {
                    "polymorphic_on":case([
                        (discriminator == "EN", "engineer"),
                        (discriminator == "MA", "manager"),
                    ], else_="employee"),
                    "polymorphic_identity":"employee"
                }

          It may also refer to any attribute
          configured with :func:`.column_property`, or to the
          string name of one::

                class Employee(Base):
                    __tablename__ = 'employee'

                    id = Column(Integer, primary_key=True)
                    discriminator = Column(String(50))
                    employee_type = column_property(
                        case([
                            (discriminator == "EN", "engineer"),
                            (discriminator == "MA", "manager"),
                        ], else_="employee")
                    )

                    __mapper_args__ = {
                        "polymorphic_on":employee_type,
                        "polymorphic_identity":"employee"
                    }

          .. versionchanged:: 0.7.4
              ``polymorphic_on`` may be specified as a SQL expression,
              or refer to any attribute configured with
              :func:`.column_property`, or to the string name of one.

          When setting ``polymorphic_on`` to reference an
          attribute or expression that's not present in the
          locally mapped :class:`.Table`, yet the value
          of the discriminator should be persisted to the database,
          the value of the
          discriminator is not automatically set on new
          instances; this must be handled by the user,
          either through manual means or via event listeners.
          A typical approach to establishing such a listener
          looks like::

                from sqlalchemy import event
                from sqlalchemy.orm import object_mapper

                @event.listens_for(Employee, "init", propagate=True)
                def set_identity(instance, *arg, **kw):
                    mapper = object_mapper(instance)
                    instance.discriminator = mapper.polymorphic_identity

          Where above, we assign the value of ``polymorphic_identity``
          for the mapped class to the ``discriminator`` attribute,
          thus persisting the value to the ``discriminator`` column
          in the database.

          See also:

          :ref:`inheritance_toplevel`

        :param polymorphic_identity: Specifies the value which
          identifies this particular class as returned by the
          column expression referred to by the ``polymorphic_on``
          setting.  As rows are received, the value corresponding
          to the ``polymorphic_on`` column expression is compared
          to this value, indicating which subclass should
          be used for the newly reconstructed object.

        :param properties: A dictionary mapping the string names of object
           attributes to :class:`.MapperProperty` instances, which define the
           persistence behavior of that attribute.  Note that :class:`.Column`
           objects present in
           the mapped :class:`.Table` are automatically placed into
           ``ColumnProperty`` instances upon mapping, unless overridden.
           When using Declarative, this argument is passed automatically,
           based on all those :class:`.MapperProperty` instances declared
           in the declared class body.

        :param primary_key: A list of :class:`.Column` objects which define the
           primary key to be used against this mapper's selectable unit.
           This is normally simply the primary key of the ``local_table``, but
           can be overridden here.

        :param version_id_col: A :class:`.Column`
           that will be used to keep a running version id of mapped entities
           in the database.  This is used during save operations to ensure that
           no other thread or process has updated the instance during the
           lifetime of the entity, else a
           :class:`~sqlalchemy.orm.exc.StaleDataError` exception is
           thrown.  By default the column must be of :class:`.Integer` type,
           unless ``version_id_generator`` specifies a new generation
           algorithm.

        :param version_id_generator: A callable which defines the algorithm
            used to generate new version ids. Defaults to an integer
            generator. Can be replaced with one that generates timestamps,
            uuids, etc. e.g.::

                import uuid

                class MyClass(Base):
                    __tablename__ = 'mytable'
                    id = Column(Integer, primary_key=True)
                    version_uuid = Column(String(32))

                    __mapper_args__ = {
                        'version_id_col':version_uuid,
                        'version_id_generator':lambda version:uuid.uuid4().hex
                    }

            The callable receives the current version identifier as its
            single argument.

        :param with_polymorphic: A tuple in the form ``(<classes>,
            <selectable>)`` indicating the default style of "polymorphic"
            loading, that is, which tables are queried at once. <classes> is
            any single or list of mappers and/or classes indicating the
            inherited classes that should be loaded at once. The special value
            ``'*'`` may be used to indicate all descending classes should be
            loaded immediately. The second tuple argument <selectable>
            indicates a selectable that will be used to query for multiple
            classes.

            See also:

            :ref:`concrete_inheritance` - typically uses ``with_polymorphic``
            to specify a UNION statement to select from.

            :ref:`with_polymorphic` - usage example of the related
            :meth:`.Query.with_polymorphic` method

    """
    return Mapper(class_, local_table, *args, **params)


def synonym(name, map_column=False, descriptor=None,
                        comparator_factory=None, doc=None):
    """Denote an attribute name as a synonym to a mapped property.

    .. versionchanged:: 0.7
        :func:`.synonym` is superseded by the :mod:`~sqlalchemy.ext.hybrid`
        extension.  See  the documentation for hybrids
        at :ref:`hybrids_toplevel`.

    Used with the ``properties`` dictionary sent to
    :func:`~sqlalchemy.orm.mapper`::

        class MyClass(object):
            def _get_status(self):
                return self._status
            def _set_status(self, value):
                self._status = value
            status = property(_get_status, _set_status)

        mapper(MyClass, sometable, properties={
            "status":synonym("_status", map_column=True)
        })

    Above, the ``status`` attribute of MyClass will produce
    expression behavior against the table column named ``status``,
    using the Python attribute ``_status`` on the mapped class
    to represent the underlying value.

    :param name: the name of the existing mapped property, which can be
      any other ``MapperProperty`` including column-based properties and
      relationships.

    :param map_column: if ``True``, an additional ``ColumnProperty`` is created
      on the mapper automatically, using the synonym's name as the keyname of
      the property, and the keyname of this ``synonym()`` as the name of the
      column to map.

    """
    return SynonymProperty(name, map_column=map_column,
                            descriptor=descriptor,
                            comparator_factory=comparator_factory,
                            doc=doc)


def comparable_property(comparator_factory, descriptor=None):
    """Provides a method of applying a :class:`.PropComparator`
    to any Python descriptor attribute.

    .. versionchanged:: 0.7
        :func:`.comparable_property` is superseded by
        the :mod:`~sqlalchemy.ext.hybrid` extension.  See the example
        at :ref:`hybrid_custom_comparators`.

    Allows any Python descriptor to behave like a SQL-enabled
    attribute when used at the class level in queries, allowing
    redefinition of expression operator behavior.

    In the example below we redefine :meth:`.PropComparator.operate`
    to wrap both sides of an expression in ``func.lower()`` to produce
    case-insensitive comparison::

        from sqlalchemy.orm import comparable_property
        from sqlalchemy.orm.interfaces import PropComparator
        from sqlalchemy.sql import func
        from sqlalchemy import Integer, String, Column
        from sqlalchemy.ext.declarative import declarative_base

        class CaseInsensitiveComparator(PropComparator):
            def __clause_element__(self):
                return self.prop

            def operate(self, op, other):
                return op(
                    func.lower(self.__clause_element__()),
                    func.lower(other)
                )

        Base = declarative_base()

        class SearchWord(Base):
            __tablename__ = 'search_word'
            id = Column(Integer, primary_key=True)
            word = Column(String)
            word_insensitive = comparable_property(lambda prop, mapper:
                            CaseInsensitiveComparator(mapper.c.word, mapper)
                        )


    A mapping like the above allows the ``word_insensitive`` attribute
    to render an expression like::

        >>> print SearchWord.word_insensitive == "Trucks"
        lower(search_word.word) = lower(:lower_1)

    :param comparator_factory:
      A PropComparator subclass or factory that defines operator behavior
      for this property.

    :param descriptor:
      Optional when used in a ``properties={}`` declaration.  The Python
      descriptor or property to layer comparison behavior on top of.

      The like-named descriptor will be automatically retrieved from the
      mapped class if left blank in a ``properties`` declaration.

    """
    return ComparableProperty(comparator_factory, descriptor)


@sa_util.deprecated("0.7", message=":func:`.compile_mappers` "
                            "is renamed to :func:`.configure_mappers`")
def compile_mappers():
    """Initialize the inter-mapper relationships of all mappers that have
    been defined.

    """
    configure_mappers()


def clear_mappers():
    """Remove all mappers from all classes.

    This function removes all instrumentation from classes and disposes
    of their associated mappers.  Once called, the classes are unmapped
    and can be later re-mapped with new mappers.

    :func:`.clear_mappers` is *not* for normal use, as there is literally no
    valid usage for it outside of very specific testing scenarios. Normally,
    mappers are permanent structural components of user-defined classes, and
    are never discarded independently of their class.  If a mapped class itself
    is garbage collected, its mapper is automatically disposed of as well. As
    such, :func:`.clear_mappers` is only for usage in test suites that re-use
    the same classes with different mappings, which is itself an extremely rare
    use case - the only such use case is in fact SQLAlchemy's own test suite,
    and possibly the test suites of other ORM extension libraries which
    intend to test various combinations of mapper construction upon a fixed
    set of classes.

    """
    mapperlib._CONFIGURE_MUTEX.acquire()
    try:
        while _mapper_registry:
            try:
                # can't even reliably call list(weakdict) in jython
                mapper, b = _mapper_registry.popitem()
                mapper.dispose()
            except KeyError:
                pass
    finally:
        mapperlib._CONFIGURE_MUTEX.release()


def joinedload(*keys, **kw):
    """Return a ``MapperOption`` that will convert the property of the given
    name or series of mapped attributes into an joined eager load.

    .. versionchanged:: 0.6beta3
        This function is known as :func:`eagerload` in all versions
        of SQLAlchemy prior to version 0.6beta3, including the 0.5 and 0.4
        series. :func:`eagerload` will remain available for the foreseeable
        future in order to enable cross-compatibility.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    examples::

        # joined-load the "orders" collection on "User"
        query(User).options(joinedload(User.orders))

        # joined-load the "keywords" collection on each "Item",
        # but not the "items" collection on "Order" - those
        # remain lazily loaded.
        query(Order).options(joinedload(Order.items, Item.keywords))

        # to joined-load across both, use joinedload_all()
        query(Order).options(joinedload_all(Order.items, Item.keywords))

        # set the default strategy to be 'joined'
        query(Order).options(joinedload('*'))

    :func:`joinedload` also accepts a keyword argument `innerjoin=True` which
    indicates using an inner join instead of an outer::

        query(Order).options(joinedload(Order.user, innerjoin=True))

    .. note::

       The join created by :func:`joinedload` is anonymously aliased such that
       it **does not affect the query results**.   An :meth:`.Query.order_by`
       or :meth:`.Query.filter` call **cannot** reference these aliased
       tables - so-called "user space" joins are constructed using
       :meth:`.Query.join`.   The rationale for this is that
       :func:`joinedload` is only applied in order to affect how related
       objects or collections are loaded as an optimizing detail - it can be
       added or removed with no impact on actual results.   See the section
       :ref:`zen_of_eager_loading` for a detailed description of how this is
       used, including how to use a single explicit JOIN for
       filtering/ordering and eager loading simultaneously.

    See also:  :func:`subqueryload`, :func:`lazyload`

    """
    innerjoin = kw.pop('innerjoin', None)
    if innerjoin is not None:
        return (
             strategies.EagerLazyOption(keys, lazy='joined'),
             strategies.EagerJoinOption(keys, innerjoin)
         )
    else:
        return strategies.EagerLazyOption(keys, lazy='joined')


def joinedload_all(*keys, **kw):
    """Return a ``MapperOption`` that will convert all properties along the
    given dot-separated path or series of mapped attributes
    into an joined eager load.

    .. versionchanged:: 0.6beta3
        This function is known as :func:`eagerload_all` in all versions
        of SQLAlchemy prior to version 0.6beta3, including the 0.5 and 0.4
        series. :func:`eagerload_all` will remain available for the
        foreseeable future in order to enable cross-compatibility.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    For example::

        query.options(joinedload_all('orders.items.keywords'))...

    will set all of ``orders``, ``orders.items``, and
    ``orders.items.keywords`` to load in one joined eager load.

    Individual descriptors are accepted as arguments as well::

        query.options(joinedload_all(User.orders, Order.items, Item.keywords))

    The keyword arguments accept a flag `innerjoin=True|False` which will
    override the value of the `innerjoin` flag specified on the
    relationship().

    See also:  :func:`subqueryload_all`, :func:`lazyload`

    """
    innerjoin = kw.pop('innerjoin', None)
    if innerjoin is not None:
        return (
            strategies.EagerLazyOption(keys, lazy='joined', chained=True),
            strategies.EagerJoinOption(keys, innerjoin, chained=True)
        )
    else:
        return strategies.EagerLazyOption(keys, lazy='joined', chained=True)


def eagerload(*args, **kwargs):
    """A synonym for :func:`joinedload()`."""
    return joinedload(*args, **kwargs)


def eagerload_all(*args, **kwargs):
    """A synonym for :func:`joinedload_all()`"""
    return joinedload_all(*args, **kwargs)


def subqueryload(*keys):
    """Return a ``MapperOption`` that will convert the property
    of the given name or series of mapped attributes
    into an subquery eager load.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    examples::

        # subquery-load the "orders" collection on "User"
        query(User).options(subqueryload(User.orders))

        # subquery-load the "keywords" collection on each "Item",
        # but not the "items" collection on "Order" - those
        # remain lazily loaded.
        query(Order).options(subqueryload(Order.items, Item.keywords))

        # to subquery-load across both, use subqueryload_all()
        query(Order).options(subqueryload_all(Order.items, Item.keywords))

        # set the default strategy to be 'subquery'
        query(Order).options(subqueryload('*'))

    See also:  :func:`joinedload`, :func:`lazyload`

    """
    return strategies.EagerLazyOption(keys, lazy="subquery")


def subqueryload_all(*keys):
    """Return a ``MapperOption`` that will convert all properties along the
    given dot-separated path or series of mapped attributes
    into a subquery eager load.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    For example::

        query.options(subqueryload_all('orders.items.keywords'))...

    will set all of ``orders``, ``orders.items``, and
    ``orders.items.keywords`` to load in one subquery eager load.

    Individual descriptors are accepted as arguments as well::

        query.options(subqueryload_all(User.orders, Order.items,
        Item.keywords))

    See also:  :func:`joinedload_all`, :func:`lazyload`, :func:`immediateload`

    """
    return strategies.EagerLazyOption(keys, lazy="subquery", chained=True)


def lazyload(*keys):
    """Return a ``MapperOption`` that will convert the property of the given
    name or series of mapped attributes into a lazy load.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    See also:  :func:`eagerload`, :func:`subqueryload`, :func:`immediateload`

    """
    return strategies.EagerLazyOption(keys, lazy=True)


def lazyload_all(*keys):
    """Return a ``MapperOption`` that will convert all the properties
    along the given dot-separated path or series of mapped attributes
    into a lazy load.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    See also:  :func:`eagerload`, :func:`subqueryload`, :func:`immediateload`

    """
    return strategies.EagerLazyOption(keys, lazy=True, chained=True)


def noload(*keys):
    """Return a ``MapperOption`` that will convert the property of the
    given name or series of mapped attributes into a non-load.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    See also:  :func:`lazyload`, :func:`eagerload`,
    :func:`subqueryload`, :func:`immediateload`

    """
    return strategies.EagerLazyOption(keys, lazy=None)


def immediateload(*keys):
    """Return a ``MapperOption`` that will convert the property of the given
    name or series of mapped attributes into an immediate load.

    The "immediate" load means the attribute will be fetched
    with a separate SELECT statement per parent in the
    same way as lazy loading - except the loader is guaranteed
    to be called at load time before the parent object
    is returned in the result.

    The normal behavior of lazy loading applies - if
    the relationship is a simple many-to-one, and the child
    object is already present in the :class:`.Session`,
    no SELECT statement will be emitted.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    See also:  :func:`lazyload`, :func:`eagerload`, :func:`subqueryload`

    .. versionadded:: 0.6.5

    """
    return strategies.EagerLazyOption(keys, lazy='immediate')


def contains_alias(alias):
    """Return a :class:`.MapperOption` that will indicate to the query that
    the main table has been aliased.

    This is used in the very rare case that :func:`.contains_eager`
    is being used in conjunction with a user-defined SELECT
    statement that aliases the parent table.  E.g.::

        # define an aliased UNION called 'ulist'
        statement = users.select(users.c.user_id==7).\\
                        union(users.select(users.c.user_id>7)).\\
                        alias('ulist')

        # add on an eager load of "addresses"
        statement = statement.outerjoin(addresses).\\
                        select().apply_labels()

        # create query, indicating "ulist" will be an
        # alias for the main table, "addresses"
        # property should be eager loaded
        query = session.query(User).options(
                                contains_alias('ulist'),
                                contains_eager('addresses'))

        # then get results via the statement
        results = query.from_statement(statement).all()

    :param alias: is the string name of an alias, or a
     :class:`~.sql.expression.Alias` object representing
     the alias.

    """
    return AliasOption(alias)


def contains_eager(*keys, **kwargs):
    """Return a ``MapperOption`` that will indicate to the query that
    the given attribute should be eagerly loaded from columns currently
    in the query.

    Used with :meth:`~sqlalchemy.orm.query.Query.options`.

    The option is used in conjunction with an explicit join that loads
    the desired rows, i.e.::

        sess.query(Order).\\
                join(Order.user).\\
                options(contains_eager(Order.user))

    The above query would join from the ``Order`` entity to its related
    ``User`` entity, and the returned ``Order`` objects would have the
    ``Order.user`` attribute pre-populated.

    :func:`contains_eager` also accepts an `alias` argument, which is the
    string name of an alias, an :func:`~sqlalchemy.sql.expression.alias`
    construct, or an :func:`~sqlalchemy.orm.aliased` construct. Use this when
    the eagerly-loaded rows are to come from an aliased table::

        user_alias = aliased(User)
        sess.query(Order).\\
                join((user_alias, Order.user)).\\
                options(contains_eager(Order.user, alias=user_alias))

    See also :func:`eagerload` for the "automatic" version of this
    functionality.

    For additional examples of :func:`contains_eager` see
    :ref:`contains_eager`.

    """
    alias = kwargs.pop('alias', None)
    if kwargs:
        raise exc.ArgumentError(
                'Invalid kwargs for contains_eager: %r' % kwargs.keys())
    return strategies.EagerLazyOption(keys, lazy='joined',
            propagate_to_loaders=False, chained=True), \
        strategies.LoadEagerFromAliasOption(keys, alias=alias, chained=True)


def defer(*key):
    """Return a :class:`.MapperOption` that will convert the column property
    of the given name into a deferred load.

    Used with :meth:`.Query.options`.

    e.g.::

        from sqlalchemy.orm import defer

        query(MyClass).options(defer("attribute_one"),
                            defer("attribute_two"))

    A class bound descriptor is also accepted::

        query(MyClass).options(
                            defer(MyClass.attribute_one),
                            defer(MyClass.attribute_two))

    A "path" can be specified onto a related or collection object using a
    dotted name. The :func:`.orm.defer` option will be applied to that object
    when loaded::

        query(MyClass).options(
                            defer("related.attribute_one"),
                            defer("related.attribute_two"))

    To specify a path via class, send multiple arguments::

        query(MyClass).options(
                            defer(MyClass.related, MyOtherClass.attribute_one),
                            defer(MyClass.related, MyOtherClass.attribute_two))

    See also:

    :ref:`deferred`

    :param \*key: A key representing an individual path.   Multiple entries
     are accepted to allow a multiple-token path for a single target, not
     multiple targets.

    """
    return strategies.DeferredOption(key, defer=True)


def undefer(*key):
    """Return a :class:`.MapperOption` that will convert the column property
    of the given name into a non-deferred (regular column) load.

    Used with :meth:`.Query.options`.

    e.g.::

        from sqlalchemy.orm import undefer

        query(MyClass).options(
                    undefer("attribute_one"),
                    undefer("attribute_two"))

    A class bound descriptor is also accepted::

        query(MyClass).options(
                    undefer(MyClass.attribute_one),
                    undefer(MyClass.attribute_two))

    A "path" can be specified onto a related or collection object using a
    dotted name. The :func:`.orm.undefer` option will be applied to that
    object when loaded::

        query(MyClass).options(
                    undefer("related.attribute_one"),
                    undefer("related.attribute_two"))

    To specify a path via class, send multiple arguments::

        query(MyClass).options(
                    undefer(MyClass.related, MyOtherClass.attribute_one),
                    undefer(MyClass.related, MyOtherClass.attribute_two))

    See also:

    :func:`.orm.undefer_group` as a means to "undefer" a group
    of attributes at once.

    :ref:`deferred`

    :param \*key: A key representing an individual path.   Multiple entries
     are accepted to allow a multiple-token path for a single target, not
     multiple targets.

    """
    return strategies.DeferredOption(key, defer=False)


def undefer_group(name):
    """Return a :class:`.MapperOption` that will convert the given group of
    deferred column properties into a non-deferred (regular column) load.

    Used with :meth:`.Query.options`.

    e.g.::

        query(MyClass).options(undefer("group_one"))

    See also:

    :ref:`deferred`

    :param name: String name of the deferred group.   This name is
     established using the "group" name to the :func:`.orm.deferred`
     configurational function.

    """
    return strategies.UndeferGroupOption(name)

from sqlalchemy import util as _sa_util
_sa_util.importlater.resolve_all()
